AI-Enhanced Wide-Area Data Imaging via Massive Non-Orthogonal Direct Device-to-HAPS Transmission

TL;DR

This paper introduces AI-enhanced data imaging for wide-area ground data reconstruction using a high-altitude pseudo-satellite and distributed sensors, employing novel neural network approaches for improved accuracy and real-time processing.

Contribution

It proposes two AI-based post-processing methods for MAP-X, including online DNN estimation and offline CNN reconstruction, and a ground-HAPS cooperation framework for training data collection.

Findings

Both AI approaches outperform IDFT-based linear methods.

Simulation results demonstrate improved reconstruction accuracy.

Framework enables real-time, high-precision wide-area data mapping.

Abstract

Massive Aerial Processing for X MAP-X is an innovative framework for reconstructing spatially correlated ground data, such as environmental or industrial measurements distributed across a wide area, into data maps using a single high altitude pseudo-satellite (HAPS) and a large number of distributed sensors. With subframe-level data reconstruction, MAP-X provides a transformative solution for latency-sensitive IoT applications. This article explores two distinct approaches for AI integration in the post-processing stage of MAP-X. The DNN-based pointwise estimation approach enables real-time, adaptive reconstruction through online training, while the CNN-based image reconstruction approach improves reconstruction accuracy through offline training with non-real-time data. Simulation results show that both approaches significantly outperform the conventional inverse discrete Fourier transform (IDFT)-based linear post-processing method. Furthermore, to enable AI-enhanced MAP-X, we propose a ground-HAPS cooperation framework, where terrestrial stations collect, process, and relay training data to the HAPS. With its enhanced capability in reconstructing field data, AI-enhanced MAP-X is applicable to various real-world use cases, including disaster response and network management.